Speedup of the Quantum Adiabatic Algorithm using Delocalization Catalysis

TL;DR

This paper introduces a catalysis-based approach using many-body delocalization to accelerate the quantum adiabatic algorithm, demonstrated through numerical simulations and small-scale quantum computer experiments, with promising scalability.

Contribution

It presents a novel catalysis technique leveraging delocalization to enhance quantum adiabatic algorithms, supported by numerical and experimental evidence.

Findings

Speedup achieved in random-field Ising model ground state search

Speedup correlates with gap amplification near delocalization transition

Experimental verification on small IBM quantum computer

Abstract

We propose a method to speed up the quantum adiabatic algorithm using catalysis by many-body delocalization. This is applied to random-field antiferromagnetic Ising spin models. The algorithm is catalyzed in such a way that the evolution approximates a Heisenberg model in the middle of its course, and the model is in a delocalized phase. We show numerically that we can speed up the standard algorithm for finding the ground state of the random-field Ising model using this idea. We also demonstrate that the speedup is due to gap amplification, even though the underlying model is not frustration-free. The crossover to speedup occurs at roughly the value of the interaction which is known to be the critical one for the delocalization transition. We also calculate the participation ratio and entanglement entropy as a function of time: their time dependencies indicate that the system is exploring more states and that they are more entangled than when there is no catalyst. Together, all these pieces of evidence demonstrate that the speedup is related to delocalization. Even though only relatively small systems can be investigated, the evidence suggests that the scaling of the method with system size is favorable. Our method is illustrated by experimental results from a small online IBM quantum computer, showing how to verify the method in future as such machines improve. The cost of the catalytic method compared to the standard algorithm is only a constant factor.